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Nuclear Chemistry. Remember when we ionize… . The ELECTRONS only get moved to change the charge on an atom. WHY don’t the PROTONS move when we ionize?. When we change the number of protons, we change the element completely into another element!. Isotopes. Same element
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Remember when we ionize… • The ELECTRONS only get moved to change the charge on an atom. • WHY don’t the PROTONS move when we ionize?
When we change the number of protons, we change the element completely into another element!
Isotopes • Same element • Same number of protons • Same atomic number • Same number of electrons • Different number of neutrons • Different mass number
Isotope short-hand …it is referred to as “Carbon 12” Mass number 12 C 6 Atomic number Atomic symbol So how many neutrons in this carbon?
And this? 14 C 6 …is called “Carbon 14” There are 2 extra neutrons
A note about Atomic Mass… • atomic mass listed on the periodic table is the weighted average of mass of all the isotopes of an atom.
Stability • of isotopes is based on the ratio of the neutrons and protons in the atoms’ nucleus. • although most nuclei are stable, some are unstable and spontaneously decay emitting radiation
Transmutation • when the nucleus of an atom that converts it from one element to another • i.e. we change the PROTONS • can occur naturally or can be induced by the bombardment of the nucleus by high-energy particles. • since the # of protons (atomic #) determines the atom, we CHANGE THE ELEMENT COMPLETELY.
Nuclear Reactions • include • naturaltransmutation • artificial transmutation, • fission, and • fusion.
Natural Transmutation • describes nuclear changes due to natural radioactivity without any human intervention. • Example: Radioactive Carbon-14 will decay to stable Nitrogen- 14 without any assistance.
Artificial Transmutation • An artificially induced nuclear rxncaused by the bombardment of a nucleus with subatomic particles (usually neutrons) or small nuclei (Hydrogen or Helium). • In 1919 Ernest Rutherford bombarded nitrogen with alpha particles and converted it to hydrogen and oxygen, thus producing the first artificial transmutation of elements.
Rate of Decay • Some radioactive atoms decay at a faster rate than others. • The rate of decay is a chemical property of the atom and cannot be changed.
Drag Out Your Reference tables
Half-Lives • Because it takes so long for all of an isotope to decay, scientists use the length of time it takes for one-half of the original amount to decay. • This period is called the half life. • •Half life – the time required for one half the mass of a radioactive sample to decay.
Nothing changes Half Life • The rate of decay for a radioactive sample is a set property of the sample. • What happens to the half-life of a sample when you; • Increase the Temperature? • Nothing changes half-life • Decrease the Temperature? • Nothing changes half-life • Increase the Surface Area? (i.e. grind it up) • Nothing changes half-life • Increase the Pressure? • Nothing changes half-life
Nuclear Chemistry Part II
Types of Decay • Alpha Decay emits an alpha particle. • The new atom's atomic number is lowered by two and its atomic mass number is reduced by four.
Types of Decay • Beta Decay emission of electrons from the nucleus • The new atom's atomic number is raised by one and its atomic mass stays the same.
Types of Decay • Positron Decay is the similar to Beta Decay except the particle released has a positive charge • The new atom's atomic number is lowered by one and its atomic mass stays the same.
Types of Decay • Gamma Decay is the release of stored energy from the nucleus. • No transmutation occurs. • gamma decay often occurs with alpha and beta negative decay in a disintegration series.
Nuclear Energy • Energy released in a nuclear reaction (fission or fusion) comes from the fractional amount of mass converted into energy. • Nuclear changes convert matter into energy. • From Einstein E=mC2 • Energy released during nuclear reactions is much greater than the energy released during chemical reactions. • There are benefits and risks associated with fission and fusion reactions.
Fission Rxns • occur when a large nucleus splits into two or more smaller nuclei plus some by-products. • By-products include free neutrons and photons (usually gamma rays). • Fission releases substantial amounts of energy
Fusion • Two or more smaller nuclei merge to form a larger nucleus, lots of energy and some by-products • Nuclei of two isotopes of hydrogen, deuterium (D) and tritium (T) react to produce a Helium (He) nucleus and a neutron (n).
Uses of Radioisotopes • used in medicine • industrial chemistry • radioactive dating • tracing chemical and biological processes • industrial measurement • nuclear power, • detection and treatment of diseases.
Geology Uses • Radiometric dating- a process in which scientists attempt to determine the ratio of parent nuclei to daughter nuclei within a given sample of a rock or fossil. • This ratio is then used to determine the absolute age of the rock or fossil. • C-14 to C-12 ratio in dating organic things • U-238 to Pb-206 ratio in dating crustal rocks
Risks • There are inherent risks associated with radioactivity and the use of radioactive isotopes. • Risks can include biological exposure, long-term storage and disposal, and nuclear accidents.
Biological exposure • All radiation can cause damage to organisms. • Most long-term damage is caused by the ionization of the atoms that make up the molecules in DNA. • If the damaged DNA are found in egg or sperm cells, the effects may be passed on for many generations (mutations)
Long-term storage and disposal • Fission reactions in produce radioactive wastes. • The wastes may have very long half-lives which make it difficult to dispose of them. • Some solids and liquids need to be encased in special containers and permanently stored underground. • Other materials are held until there radioactivity has lessened and are then diluted with other materials and released back into the environment.
Nuclear accidents • An example of nuclear accident might be one in which a reactor core is damaged such as Three Mile Island (near Harrisburg PA) or Chernobyl, Ukraine and Fukishima, Japan. • radiography accident where a worker drops the source into a river or sticks it in his pocket. • Due to government and business secrecy, it is difficult to determine with certainty the extent of some events.
82 [1] Allow 1 credit. Acceptable responses include, but are not limited to: • The nuclides used for fusion have smaller atomic masses than nuclides used for fission. • The nuclides used in fission are many times more massive. • Fusion particles are lighter.
83 [1] Allow 1 credit for the correct number of protons and the correct number of neutrons for both • hydrogen nuclides. • Example of a 1-credit response:
85 [1] Allow 1 credit. Acceptable responses include, but are not limited to: • Fusion produces more energy per gram of reactant. • The fusion process produces less radioactive waste. • The fusion reactant material is more readily available.